KR20210145404A - Capacitance type wave height meter calibration system and calibration method - Google Patents

Abstract

The present invention relates to a calibration system and a calibration method for a capacitive wave gauge, and specifically, to a calibration system and a calibration method for a capacitive wave gauge, wherein the calibration system is capable of accurately and easily measuring the wave height when conducting a model test of a model ship. The calibration system for a capacitive wave gauge of the present invention includes: an underwater lift; a level sensor; and a control unit. The calibration system for a capacitive wave gauge is configured to detect a capacitance value that varies in accordance with a change in water level through a capacity wire of a capacitive wave gauge since a model ship to which a plurality of capacity wires of the capacitive wave gauges are attached is configured to go up and down by an underwater lift placed in a water tank.

Description

Capacitance type wave height meter calibration system and calibration method }

The present invention relates to a capacitive crest meter calibration system and calibration method, and more particularly, to a capacitive crest meter calibration system and calibration method that can accurately and simply measure the crest height when a model test of a model ship is carried out.

A wave height meter is a device that measures the height of waves.

Wave measurement is the most frequently performed and most important task in the study of mathematical model experiments in the fields of coastal engineering and marine engineering.

Wave height measurement is a continuous measurement of water surface elevation moving with time.

The wave height is measured using a detection wire whose voltage varies linearly according to the displacement of the water surface, and the signal of the detection line is output in analog form, but it is converted into a digital signal having a constant sampling interval and connected to the wave height meter. Save it to your computer.

There are two types of crest gauges: resistance-type crest gauges and capacitive-type crest gauges.

A resistance wave gauge consists of two parallel detection lines of equal length.

High-frequency AC voltage flows along the detection line, and the wave height can be measured using the characteristic that the conductivity changes as the height of the water surface changes.

Such a resistance-type crest meter has the advantage of exhibiting a fairly good linear response characteristic of a resistance value according to a change in water level, and excellent resolution.

However, since the conductivity of water changes according to salinity and temperature, there is a disadvantage that the calibration of the crest meter needs to be performed frequently.

Calibration of the wave height meter must be carried out before starting the experiment, and in case of a large daily temperature difference, it is desirable to calibrate at least twice a day in the morning and in the afternoon.

Capacitance wave gauge consists of a thin insulated detection wire and a support rod supporting and supporting the wire.

As the cross-sectional area of the support rod is made as small as possible, disturbance of fluid motion can be minimized.

If the insulation thickness of the detection line is uniform and there is no insulation break in the middle of the detection line, the capacitive crest meter changes linearly according to the water level change.

If the detection line of the capacitive wave meter is clean and well maintained, it can be used stably for a fairly long time.

If dust or contaminants floating on the surface of the water adhere to the detection line during the experiment, it may show an unusual value, so be careful.

Recently, a capacitive crest meter has been mainly used, and the principle of such a capacitive crest meter is as follows.

When an insulated detection wire whose axis is made of a conductor is placed in water, a condenser is formed between the conductor and water.

Since water is set to 0 level (G: Ground), a potential difference is generated between the metal conductor and the insulator between them, so that the insulator moves.

The capacitance of the condenser part changes as the water depth changes, and this change is proportional. As the water depth increases, the capacitance increases, and when the water depth decreases, the capacitance decreases.

This capacitance is converted to a voltage proportional to it inside the detection, and the voltage is amplified by the DC amplifier inside the main body once again, and the change from the reference level is converted to a numerical value and output.

That is, an oscillator that detects a capacitance value that varies according to the displacement of the wave height through the detection line of the capacitive crest meter, and provides an oscillation frequency by an induced voltage that is changed according to the variable capacitance (CV) value; By converting the oscillation frequency into a crest amount through the filter unit that removes the noise component and the amplifier unit that amplifies the oscillation frequency filtered by the filter unit, the crest measurement becomes possible.

Conventionally, after individually calibrating the detection line of the capacitive wave height meter, it was attached to the model ship, and then the model test was carried out without additional calibration value verification work.

In the case of the capacitive crest meter, since the signal detection principle is to detect the change in capacitance as described above, there is inevitably a change in the signal depending on the installation environment.

Conventionally, since the calibration of the detection line is carried out in a tank without obstructions around the detection line, there is a problem in that the wave height measurement is inaccurate in the case of an actual model test.

In addition, there is a problem in that it takes a lot of time to prepare the model test because the detection line of the capacitive wave height meter has to be individually calibrated and then attached to the model ship.

In addition, in the related art, since it is necessary to visually check how much the model ship vertically moved up and down in the tank using a steel ruler, there is a problem in that it is inefficient and the accuracy is lowered.

KR 10-2067166 B1 (2020.02.11. Announcement)

An object of the present invention is that when the calibration of the detection line is carried out in a water tank without obstructions around the detection line as in the prior art, it is different from the environment in the case of the actual model test. It is to provide a capacitive crest meter calibration system and calibration method that can accurately and simply measure the crest height by performing calibration after attaching all the capacity wires.

Another object of the present invention is to save time by performing calibration after attaching all of the capacity wires to the model ship instead of individually calibrating the detection lines of the capacitive crest meter as in the prior art and then attaching them to the model ship. It is to provide a capacitive crest meter calibration system and calibration method that can do this.

Another object of the present invention is to provide a capacitive wave height meter calibration system and calibration method that can increase the efficiency of work by simply and accurately checking how much the model ship vertically moved up and down in the water tank.

The capacitive wave height gauge calibration system of the present invention for achieving the above object is made so that a model ship to which a plurality of capacitive wave height detection wires (capacity wires) are attached is lifted up and down by an underwater lift disposed in a water tank, It is characterized in that it is configured to detect the capacitance value that varies according to the change through the detection line of the capacitive crest meter.

As described above, the capacitive crest meter calibration system according to the present invention is configured to detect a capacitance value that varies according to a change in water level through a detection line of a capacitive crest meter, and is disposed in a water tank, and a plurality of detection lines ( an underwater lift that raises and lowers model ships with capacity wires attached; a level sensor disposed on one side of the underwater lift to measure the water level in the water tank; and a control unit that receives the measurement signal from the level sensor and operates the underwater lift to control the model ship to be raised and lowered to a desired height.

In this case, the underwater lift may include: a seating part horizontally disposed on the upper part of the water tank so that the model ship is seated; a support part spaced apart from the seating part and horizontally disposed on the floor in the water tank; a connection part disposed between the seating part and the support part to connect the seating part and the support part; and elevating means for providing a driving force to the connection part so that the seating part can be lifted up and down.

The seating portion may include a plurality of hollow pipes spaced apart from each other and arranged in parallel.

In addition, the support unit includes a pair of first support frames disposed on the floor in the water tank in parallel with each other spaced apart from each other, and a pair of second support frames connecting both ends of the pair of first support frames, respectively. do.

In addition, the connecting portion may include: a first support shaft disposed between the pair of first support frames in a direction perpendicular to the longitudinal direction of the first support frame, and both ends of which are respectively fixed to the pair of first support frames; A second support disposed between the pair of first support frames to be spaced apart from the first support shaft in a longitudinal direction and a right angle direction of the first support frame so that both ends are respectively fixed to the pair of first support frames. axis; a third support shaft fixed to a bottom surface of the seating part to correspond to the first support shaft; a fourth support shaft fixed to a bottom surface of the seating part to correspond to the second support shaft; a first connection frame having one end rotatably coupled to one end of the first support shaft and the other end rotatably coupled to one end of the fourth support shaft; a second connection frame having one end rotatably coupled to one end of the second support shaft and the other end rotatably coupled to one end of the third support shaft; a third connection frame having one end rotatably coupled to the other end of the first support shaft and the other end rotatably coupled to the other end of the fourth support shaft; a fourth connection frame having one end rotatably coupled to the other end of the second support shaft and the other end rotatably coupled to the other end of the third support shaft; and disposed in a direction perpendicular to the longitudinal direction of the first support frame, one end coupled to the longitudinal center of the first connecting frame and the second connecting frame, and the other end being the length of the third connecting frame and the fourth connecting frame. and a fifth support shaft coupled to the central portion in the direction, wherein the first to fourth connection frames are rotatably coupled with respect to the fifth support shaft.

In addition, the elevating means is disposed between the first connection frame and the third connection frame, the lower side of the first connection frame located below the longitudinal central portion and the lower side of which both ends are fixed to the lower side of the third connection frame. support shaft; an upper support shaft disposed between the second connection frame and the fourth connection frame and having both ends fixed to an upper side of the second connection frame and an upper side of the fourth connection frame located above the central portion in the longitudinal direction; and a hydraulic cylinder including a cylinder fixed to the lower support shaft, and a piston rod that linearly reciprocates within the cylinder and has an end exposed to the outside of the cylinder and fixed to the upper support shaft.

On the other hand, the capacitive crest meter calibration system according to the present invention holds a plurality of cables including cables connected to the detection lines (capacity wires) of a plurality of capacitive crest meters attached to the model ship so as not to fall into the water tank in an underwater lift. It may further include a cable holder to be installed.

At this time, the cable holder is provided to be foldable in the underwater lift.

The cable holder, such as, is made of a predetermined length, one end of the first holder is hinged to the upper end side of the underwater lift; and a second holder made of a predetermined length, one end of which is hinged to the other end of the first holder; Next, when the second holder is deployed horizontally and the calibration of the capacitive wave meter is not performed, the second holder is stacked to overlap the first holder, and then the first holder is horizontally placed on the upper end of the underwater lift. It is characterized in that it is made to be foldable.

Moreover, it is preferable that the said level sensor is an ultrasonic level sensor.

In addition, the capacitive wave height calibration system according to the present invention may further include a display unit for receiving and displaying information about the water level in the water tank measured from the level sensor.

On the other hand, the capacitive crest meter calibration method according to another aspect of the present invention is characterized in that the capacitive crest meter is calibrated using the above-described capacitive crest meter calibration system.

Specific details of other embodiments are included in "Details for carrying out the invention" and the accompanying "drawings".

Advantages and/or features of the present invention, and methods of achieving them, will become apparent with reference to the various embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the configuration of each embodiment disclosed below, but may also be implemented in a variety of different forms, and each embodiment disclosed in this specification only makes the disclosure of the present invention complete, It is provided to fully inform those of ordinary skill in the art to which the invention pertains to the scope of the present invention, and it should be understood that the present invention is only defined by the scope of each claim.

According to the present invention, if the calibration of the detection line is carried out in a water tank without obstructions around the detection line as in the prior art, it is different from the environment in the case of the actual model test, so it is necessary to review the calibration value. After attaching all the capacity wires to the pole, it is possible to accurately and simply measure the crest height by calibrating the capacitive crest meter using an underwater lift.

In addition, according to the present invention, the detection line of the capacitive crest meter is individually calibrated as in the prior art and then is not attached to the model ship. can be saved.

In addition, according to the present invention, by providing a level sensor and a display unit, it is possible to easily and accurately check how much the model ship vertically moved up and down in the water tank, thereby increasing work efficiency.

In addition, according to the present invention, by providing the cable holder in the underwater lift, a plurality of cables including the cables connected to the detection lines (capacity wires) of a plurality of capacitive wave meters attached to the model ship are held in order to not fall into the water tank. be able to avoid it.

In addition, in the case of the present invention, by configuring the cable holder to be foldable in the underwater lift when the calibration work of the capacitive wave height meter is not performed, it is possible to provide convenience in transporting or maintaining the underwater lift.

In addition, according to the present invention, by receiving the measurement signal from the level sensor and operating the underwater lift to elevate the model ship to a desired height, the efficiency and accuracy of the work can be improved.

1 is a view schematically showing a capacitive crest meter calibration system according to the present invention.
Figure 2 is a view showing the underwater lift employed in the capacitive wave height calibration system according to the present invention.
3 is a view showing a state viewed from the front of the underwater lift employed in the capacitive wave height calibration system according to the present invention.
FIG. 4 is a plan view of FIG. 3 .
FIG. 5 is a side view of FIG. 3 ;
6 is a view showing a state in which the underwater lift of FIG. 3 is folded.
7 is a view showing a folded state of the sensor cable holder employed in the capacitive wave height calibration system according to the present invention.
8 is a view showing a state in which the sensor cable holder of FIG. 1 is viewed from the side.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Before describing the present invention in detail, the terms or words used in this specification should not be construed as being unconditionally limited to their ordinary or dictionary meanings, and in order for the inventor of the present invention to explain his invention in the best way It should be understood that the concepts of various terms can be appropriately defined and used, and furthermore, these terms or words should be interpreted as meanings and concepts consistent with the technical idea of the present invention.

That is, the terms used herein are only used to describe preferred embodiments of the present invention, and are not used for the purpose of specifically limiting the content of the present invention, and these terms represent various possibilities of the present invention. It should be understood that the term has been defined taking into account.

In addition, in the present specification, it should be noted that, unless the context clearly indicates otherwise, the expression in the singular may include a plurality of expressions, and even if it is similarly expressed in plural, it may include the meaning of the singular. do.

In the case where it is stated throughout this specification that a component "includes" another component, it does not exclude any other component, but further includes any other component unless otherwise stated. It could mean that you can.

Furthermore, when it is described that a component is "exists in or connected to" of another component, this component may be directly connected to or installed in contact with another component, and a certain It may be installed spaced apart by a distance, and in the case of being installed spaced apart by a certain distance, a third component or means for fixing or connecting the component to another component may exist, and now It should be noted that the description of the components or means of 3 may be omitted.

On the other hand, when it is described that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the third element or means does not exist.

Similarly, other expressions describing the relationship between components, such as "between" and "immediately between", or "neighboring to" and "directly adjacent to", have the same meaning. should be interpreted as

In addition, in this specification, terms such as "one side", "other side", "one side", "other side", "first", "second", etc., if used, for one component, this single component It is used to be clearly distinguished from other components, and it should be understood that the meaning of the component is not limitedly used by such terms.

In addition, in the present specification, terms related to positions such as "upper", "lower", "left", and "right", if used, should be understood as indicating a relative position in the drawing with respect to the corresponding component, Unless an absolute position is specified with respect to their position, these position-related terms should not be construed as referring to an absolute position.

Moreover, in the specification of the present invention, terms such as “…unit”, “…group”, “module”, “device”, etc., if used, mean a unit capable of processing one or more functions or operations, which means hardware Alternatively, it should be understood that it may be implemented in software, or a combination of hardware and software.

In addition, in this specification, in specifying the reference numerals for each component of each drawing, the same component has the same reference number even if the component is shown in different drawings, that is, the same reference is made throughout the specification. Symbols indicate identical components.

In the drawings attached to this specification, the size, position, coupling relationship, etc. of each component constituting the present invention are partially exaggerated, reduced, or omitted for convenience of explanation or in order to sufficiently clearly convey the spirit of the present invention. may be described, and therefore the proportion or scale may not be exact.

In addition, in the following, in describing the present invention, a detailed description of a configuration determined that may unnecessarily obscure the gist of the present invention, for example, a detailed description of a known technology including the prior art may be omitted.

1 is a view schematically showing a capacitive crest meter calibration system according to the present invention.

The capacitive crest meter calibration system according to the present invention is such that the model ship M to which the detection wires W of a plurality of capacitive crest meters are attached is lifted up and down by the underwater lift 10 disposed in the water tank. It is made to sense the capacitance value, which varies according to the change of the water level, through the detection line (W) of the capacitive crest meter.

The capacitive wave height calibration system according to the present invention, as described above, includes an underwater lift 10, a level sensor 20 and a control unit (not shown).

The underwater lift 10 is disposed in the water tank and elevates the model ship M to which the detection wires W of a plurality of capacitive wave meters are attached, which will be described later.

The level sensor 20 is disposed on one side of the underwater lift 10 to measure the water level in the water tank.

A level sensor is a sensor that measures water level, and this level sensor, that is, a level sensor, is divided into two types.

A point level sensor is used to indicate the current level condition, which is a single distinct liquid level.

In general, this type of level sensor can also function as a water level indicator to set and notify when the water level is too low or too high.

Level sensors for continuous water levels are more sophisticated as capacitive sensors and can provide level monitoring for the entire system.

These sensors measure the fluid level in the vessel rather than at a point and produce an analog output that has a direct relationship to the level in the vessel.

This output signal can be linked to a process control loop and a display (indicator) to build a water level measurement system.

The types of such level sensors are as follows.

① A level switch (float switch), a contact level sensor, moves along the surface of a magnetically floating liquid in a point level sensor and operates a closed reed switch at the center.

Its simple, low-maintenance design allows for easy installation, minimizes shock, vibration and pressure, and can be used with a variety of media.

The reed switch is a single point single throw (SPST) type or a single point double throw (SPDT) type.

② The non-contact ultrasonic level sensor includes an analog signal processing unit, a microprocessor, a binary-coded decimal (BCD) range switch, and an output driver circuit.

The pulse and gate signals are transmitted from the path of the microprocessor to the sensor through the analog signal processing device, and the sensor illuminates the ultrasonic wave onto the liquid surface.

The sensor detects the echo from the surface and sends it back to the microprocessor to digitally represent the distance between the sensor and the surface water level.

Through continuous updating of the received signal, the microprocessor calculates an average value for the measurement of the liquid level.

For the persistence sensor, the microprocessor converts the average value into an analog signal from 4 to 20 mA that is linear with the liquid level.

If the echo from the water level does not return to the sensor within 8 seconds, the output signal of the system will drop below 4 mA, indicating a low water level condition or empty piping.

For point sensors, the microprocessor compares the average value to the BCD transition setting and energizes the output relay for a high or low level indication.

Signal loss longer than 8 seconds will cut the relay's power supply and restore it to its original state.

The sensor has a delay of 0.5 sec which minimizes the effect of surface turbulence.

③ Low-energy ultrasonic equipment belonging to the contact ultrasonic level sensor measures the liquid level at a specific point.

It consists of a field mountable sensor and a built-in solid-state amplifier. The contact ultrasonic sensor has no moving parts and requires no calibration.

Usually these sensors are equipped with a terminal block for connection to a power source and external control.

An ultrasonic signal traverses a half-inch gap in the sensor to control the relay switch if there is liquid in the gap.

The sensing level is located midway along the crevice for horizontally mounted sensors and above the crevice for vertically mounted sensors.

When the liquid falls below this level, the ultrasonic signal weakens and eventually reverts the relay to its previous state.

These sensors are used in vessels or pipelines to automatically trigger pumps, solenoid valves and high/low alarms.

Two may be needed to fill an empty tank and measure the liquid volume.

It is compatible with most liquids and is unaffected by coatings, water droplets, bubbles and vapors.

However, liquids with a high carbon dioxide content or liquids with a high viscosity that fill the gaps in the sensor can cause problems.

④ Like ultrasonic sensors, capacitive sensors measure point levels or sustained water levels.

These sensors monitor changes in the liquid level in the tank with a sensor probe, and electronically adjust the outputs for capacity and resistance values, converting the measured values into analog signals.

The probe and vessel wall are identical to the two plates of the capacitor from liquid to dielectric medium.

Since the signal is generated only by a change in water level, the material does not attach to the sensor probe and affect the measurement result.

However, for non-conductive liquid containers, this may affect double probes or external conductive strips.

There are two types of probes: a rigid type and a flexible type.

Usually, conductors insulated with PTFE are used.

Stretchable probes are used in applications where there is not enough space for a rigid metal probe or require very long lengths.

Rugged type probe materials usually use stainless steel and provide the added sensitivity needed to measure liquids that are non-conductive, granular, or have low dielectric properties (permittivity lower than 4).

Robust probes provide high stability, especially in turbulent flow systems, where probe oscillations cause signal fluctuations.

As described above, although there are various types of level sensors, the level sensor 20 employed in the present invention is preferably a non-contact ultrasonic level sensor.

The control unit (not shown) receives the measurement signal from the level sensor 20 and operates the underwater lift 10 to control the model ship M to be raised and lowered to a desired height, and may be installed in the underwater lift 10 . Also, it may be installed separately from the underwater lift 10 .

On the other hand, the capacitive wave height calibration system according to the present invention may further include a display unit 50 for receiving and displaying information about the water level in the water tank measured from the level sensor 20 .

By linking the level sensor 20 and the display unit 50 in this way, it is possible to easily and accurately check how much the model ship M vertically moved up and down in the water tank, thereby increasing work efficiency. .

Figure 2 is a view showing the underwater lift employed in the capacitive wave height calibration system according to the present invention, Figure 3 is a view showing the state viewed from the front of the underwater lift employed in the capacitive wave height calibration system according to the present invention.

Also, FIG. 4 is a plan view of FIG. 3 , and FIG. 5 is a side view of FIG. 3 .

The underwater lift 10 includes a seating portion 11 , a support portion 13 , a connection portion 15 , and a lifting means 17 .

The seating part 11 is horizontally disposed on the upper part of the water tank so that the model ship M is seated, and includes a plurality of hollow pipes 11a spaced apart from each other and disposed in parallel.

As such, by disposing the plurality of hollow pipes 11a to be spaced apart from each other, water in the water tank can pass between the spaced spaces, and the overall weight can be reduced by forming the pipe hollow.

The support part 13 is spaced apart from the seating part 11 and horizontally disposed on the floor in the water tank. A pair of second support frames 13b for connecting both ends of the first support frame 13a, respectively.

Accordingly, the support 13 is formed in the form of a rectangular frame.

The connection part 15 is disposed between the seating part 11 and the support part 13 to connect the seating part 11 and the support part 13, and a first between the pair of first support frames 13a. a first support shaft (S1) disposed in a direction perpendicular to the longitudinal direction of the support frame (13a) and having both ends fixed to the pair of first support frames (13a); The first support frame 13a is disposed to be spaced apart from the first support shaft S1 in the longitudinal direction and right angle direction of the first support frame 13a between the pair of first support frames 13a, so that both ends thereof are the pair of first support frames 13a. ) a second support shaft (S2) each fixed to; a third support shaft (S3) fixed to the bottom surface of the seating part 11 to correspond to the first support shaft (S1); a fourth support shaft (S4) fixed to the bottom surface of the seating unit (11) to correspond to the second support shaft (S2); One end is rotatably coupled to one end of the first support shaft (S1), the other end is a first connection frame (F1) rotatably coupled to one end of the fourth support shaft (S4); One end is rotatably coupled to one end of the second support shaft (S2), the other end is a second connection frame (F2) rotatably coupled to one end of the third support shaft (S3); One end is rotatably coupled to the other end of the first support shaft (S1), the other end is a third connection frame (F3) rotatably coupled to the other end of the fourth support shaft (S4); One end is rotatably coupled to the other end of the second support shaft (S2), the other end is a fourth connection frame (F4) rotatably coupled to the other end of the third support shaft (S3); and the first support frame (13a) disposed in a direction perpendicular to the longitudinal direction, one end coupled to the longitudinal central portion of the first connecting frame (F1) and the second connecting frame (F2), and the other end of the third connecting frame ( F3) and a fifth support shaft (S5) coupled to the longitudinal central portion of the fourth connection frame (F4); includes.

At this time, the first connection frame F1 to the fourth connection frame F4 are rotatably coupled with respect to the fifth support shaft S5.

The lifting means 17 provides a driving force to the connecting portion 15 so that the seating portion 11 can be lifted up and down, and includes a lower support shaft (L), an upper support shaft (U) and a hydraulic cylinder (P). is done by

The lower support shaft (L) is disposed between the first connection frame (F1) and the third connection frame (F3), the lower side of the first connection frame (F1) and the third connection frame (F3) located below the central portion in the longitudinal direction ), both ends are fixed on the lower side.

The upper support shaft (U) is disposed between the second connection frame (F2) and the fourth connection frame (F4), the upper side of the second connection frame (F2) located above the central portion in the longitudinal direction and the fourth connection frame ( Both ends are fixed on the upper side of F4).

The hydraulic cylinder (P) has a cylinder (P1) fixed to the lower support shaft (L) and a linear reciprocating motion inside the cylinder (P1), and the end is exposed to the outside of the cylinder (P1) and fixed to the upper support shaft (U) It is composed of a piston rod (P2).

6 is a view showing a state in which the underwater lift of FIG. 3 is folded.

When the piston rod (P2) of the hydraulic cylinder (P) is pulled into the inside of the cylinder (P1) by a certain amount in the lifting means (17) of the underwater lift (10), the upper support shaft (U) to which the piston rod (P2) is coupled ) is pulled downwards.

Accordingly, the upper side of the second connection frame (F2) to which the upper support shaft (U) is fixed and the upper side of the fourth connection frame (F4) are also pulled downward, and are rotatably coupled to the fifth support shaft (S5). As the first connection frame F1 and the third connection frame F3 also move downward, the seating part 11 moves downward.

7 is a view showing a folded state of the sensor cable holder employed in the capacitive wave height calibration system according to the present invention, and FIG. 8 is a view showing the state of the sensor cable holder of FIG. 1 as viewed from the side.

The capacitive crest meter calibration system according to the present invention holds a plurality of cables including cables connected to the detection lines (capacity wires) (W) of a plurality of capacitive crest meters attached to the model ship (M) so as not to fall into the water tank. It may further include a cable holder 40 installed in the underwater lift (10).

At this time, the cable holder 40 is provided so as to be foldable in the underwater lift 10 . This cable holder 40 is made of a predetermined length, and has one end hinged to the upper end side of the underwater lift 10 . 1 holder (H1); and a second holder (H2) of a predetermined length, one end of which is hinged to the other end of the first holder (H1).

When calibrating the capacitive wave gauge, set the first holder (H1) vertically on the upper end of the underwater lift (10), then deploy the second holder (H2) horizontally and use it, and do not perform the calibration work of the capacitive wave gauge. In this case, the second holder (H2) is stacked to overlap the first holder (H1), and then the first holder (H1) is horizontally folded on the upper end of the underwater lift (10).

The first holder (H1) and the second holder (H2) are made of a hollow and a plurality of cables including a cable connected to a detection line (capacity wire) of a plurality of capacitive wave meters through the inside may be connected, and if necessary Accordingly, an additional holding device in the form of tongs may be installed in the first holder H1 or the second holder H2.

As such, when the calibration of the capacitive wave gauge is not performed, the cable holder 40 is configured to be foldable in the underwater lift 10, thereby providing convenience in transportation or maintenance of the underwater lift 10. .

On the other hand, the capacitive crest meter calibration method according to another aspect of the present invention is characterized in that the capacitive crest meter is calibrated using the above-described capacitive crest meter calibration system.

As described above, according to the method of calibrating the capacitive crest meter using the capacitive crest meter calibration system according to the present invention, if the calibration of the detection line is carried out in a water tank without obstructions around the detection line as in the prior art, the actual model test Since it is necessary to review the calibration value because it is different from the environment in the case of There are advantages that can be

In addition, the advantage of saving time by calibrating the detection line of the capacitive crest meter individually as in the prior art is not attached to the model ship, but after attaching all the capacity wires to the model ship. have.

In the above, although several preferred embodiments of the present invention have been described with some examples, the description of various various embodiments described in the "Specific Contents for Carrying Out the Invention" item is merely exemplary, and the present invention Those of ordinary skill in the art will understand well that the present invention can be practiced with various modifications or equivalents to the present invention from the above description.

In addition, since the present invention can be implemented in various other forms, the present invention is not limited by the above description, and the above description is intended to complete the disclosure of the present invention, and is usually It should be understood that this is only provided to fully inform those with knowledge of the scope of the present invention, and that the present invention is only defined by each of the claims.

10 : Underwater Lift
11: seating part
13: support
13a: first support frame
13b: second support frame
15: connection
S1: first support shaft
S2: second support shaft
S3: 3rd support shaft
S4: 4th support shaft
S5: 5th support shaft
F1: first connection frame
F2: second connection frame
F3: 3rd connection frame
F4: 4th connection frame
17: elevating means
L: lower support shaft
U: upper support shaft
P : hydraulic cylinder
P1: cylinder
P2 : piston rod
20: level sensor
40: cable holder
H1: first holder
H2: second holder
50: display unit

Claims (13)

The model ship to which the detection wires of a plurality of capacitive wave meters are attached is made to go up and down by an underwater lift placed in the water tank. characterized in that it is configured to detect,
Capacitive Crestometer Calibration System.
A capacitive crest meter calibration system configured to detect a capacitance value that varies according to a change in water level through a detection line of the capacitive crest meter,
an underwater lift disposed in the water tank and lifted up and down a model ship to which a plurality of capacitive wave height detection lines (capacity wires) are attached;
a level sensor disposed on one side of the underwater lift to measure the water level in the water tank; and
A control unit that receives the measurement signal from the level sensor and operates the underwater lift to control the model ship to be raised to a desired height; characterized in that it comprises a,
Capacitive Crestometer Calibration System.
3. The method according to claim 2,
The underwater lift is
a seating part horizontally disposed on the upper part of the water tank so that the model ship is seated;
a support part spaced apart from the seating part and horizontally disposed on the floor in the water tank;
a connection part disposed between the seating part and the support part to connect the seating part and the support part; and
Elevating means for providing a driving force to the connection portion so that the seating portion can be lifted up and down; characterized in that it comprises a,
Capacitive Crestometer Calibration System.
4. The method according to claim 3,
The seating part,
Characterized in that it comprises a plurality of hollow pipes spaced apart from each other and arranged side by side,
Capacitive Crestometer Calibration System.
4. The method according to claim 3,
The support part,
A pair of first support frames arranged on the floor in the water tank side by side while being spaced apart from each other;
Characterized in that it comprises a pair of second support frames for connecting both ends of the pair of first support frames, respectively,
Capacitive Crestometer Calibration System.
6. The method of claim 5,
The connection part,
a first support shaft disposed between the pair of first support frames in a direction perpendicular to the longitudinal direction of the first support frame and having both ends fixed to the pair of first support frames, respectively;
A second support disposed between the pair of first support frames to be spaced apart from the first support shaft in a longitudinal direction and a right angle direction of the first support frame so that both ends are respectively fixed to the pair of first support frames. axis;
a third support shaft fixed to a bottom surface of the seating part to correspond to the first support shaft;
a fourth support shaft fixed to a bottom surface of the seating part to correspond to the second support shaft;
a first connection frame having one end rotatably coupled to one end of the first support shaft and the other end rotatably coupled to one end of the fourth support shaft;
a second connection frame having one end rotatably coupled to one end of the second support shaft and the other end rotatably coupled to one end of the third support shaft;
a third connection frame having one end rotatably coupled to the other end of the first support shaft and the other end rotatably coupled to the other end of the fourth support shaft;
a fourth connection frame having one end rotatably coupled to the other end of the second support shaft and the other end rotatably coupled to the other end of the third support shaft; and
It is disposed in a direction perpendicular to the longitudinal direction of the first support frame, one end is coupled to the central portion in the longitudinal direction of the first connecting frame and the second connecting frame, and the other end is disposed in the longitudinal direction of the third connecting frame and the fourth connecting frame. A fifth support shaft coupled to the central portion; Including,
The first connection frame to the fourth connection frame are characterized in that they are rotatably coupled with respect to the fifth support shaft,
Capacitive Crestometer Calibration System.
6. The method of claim 5,
The elevating means is
a lower support shaft disposed between the first connection frame and the third connection frame, the lower support shaft having both ends fixed to the lower side of the first connection frame and the lower side of the third connection frame located below the central portion in the longitudinal direction;
an upper support shaft disposed between the second connection frame and the fourth connection frame and having both ends fixed to an upper side of the second connection frame and an upper side of the fourth connection frame located above the central portion in the longitudinal direction; and
and a hydraulic cylinder comprising a cylinder fixed to the lower support shaft and a piston rod having a linear reciprocating motion inside the cylinder and having an end exposed to the outside of the cylinder and fixed to the upper support shaft.
Capacitive Crestometer Calibration System.
3. The method according to claim 2,
It further comprises a cable holder installed in the underwater lift so as not to fall into the tank by holding a plurality of cables including cables connected to the detection lines (capacity wires) of a plurality of capacitive wave meters attached to the model ship.
Capacitive Crestometer Calibration System.
9. The method of claim 8,
The cable holder is
Characterized in that provided to be foldable in the underwater lift.
Capacitive Crestometer Calibration System.
10. The method of claim 9,
The cable holder is
A first holder made of a predetermined length, one end is hinged to one side of the upper end of the underwater lift; and
a second holder having a predetermined length, one end of which is hinged to the other end of the first holder;
When calibrating the capacitive wave meter, the first holder is vertically erected on the upper end of the underwater lift, and then the second holder is horizontally deployed and used,
When the calibration of the capacitive wave meter is not performed, the second holder is stacked to overlap the first holder, and then the first holder is horizontally folded on the upper end of the underwater lift.
Capacitive Crestometer Calibration System.
3. The method according to claim 2,
The level sensor is
characterized in that it is an ultrasonic level sensor.
Capacitive Crestometer Calibration System.
3. The method according to claim 2,
Characterized in that it further comprises a display unit for receiving and displaying information about the water level in the water tank measured from the level sensor.
Capacitive Crestometer Calibration System.
A method for calibrating a capacitive crest meter using the capacitive crest meter calibration system according to any one of claims 1 to 12.

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